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v t e

Regenerative cooling is a method of cooling gases in which compressed gas is cooled by allowing it to expand and thereby take heat from the surroundings. The cooled expanded gas then passes through a heat exchanger where it cools the incoming compressed gas.

Regenerative cycles

• Stirling cycle
• Gifford–McMahon cycle
• Vuilleumier cycle
• Pulse tube refrigerator

History

In 1857, Siemens introduced the regenerative cooling concept with the Siemens cycle. In 1895, William Hampson in England and Carl von Linde in Germany independently developed and patented the Hampson–Linde cycle to liquefy air using the Joule–Thomson expansion process and regenerative cooling. On 10 May 1898, James Dewar used regenerative cooling to become the first to statically liquefy hydrogen.

See also

• Cryocooler
• Displacer
• Fluid mechanics
• Regenerative cooling (rocket)
• Regenerative heat exchanger
• Thermodynamic cycle
• Timeline of hydrogen technologies

References

1. "Cryogenic microcooling Pag.25" (PDF). Archived from the original (PDF) on 2012-02-18. Retrieved 2008-11-06.
2. Charles William Siemens, "Improvements in refrigerating and producing ice, and in apparatus or machinery for that purpose", British patent no. 2064 (filed: July 29, 1857).
3. W. Hampson, "Improvements relating to the progressive refrigerating of gases", British patent 10,165 (filed: May 23, 1895).
4. Linde, Carl, "Verfahren zur Verflüssigung atmosphärischer Luft oder anderer Gase" (Method for the liquefication of atmospheric air or other gases), German patent 88,824 (filed: June 5, 1895).
5. Hydrogen through the Nineteenth Century

External links

• Regenerative Coolers Archived 2007-07-17 at the Wayback Machine
• Regenerative Cycle Video

• Cooling technology
• Cryogenics
• Thermodynamic cycles
• Industrial gases